ABSTRACT
An electric locomotive is a locomotive powered by electricity from overhead lines, a third rail or an on-board
energy storage device.During the course of run of the locos, there arise situations that the motor consumes
current that is above the maximum or below the minimum ratings. This phenomenon causes flashover, burning
out of contactors etc. If we could prevent these undesirable anomalies a lot of money can be saved and also the
maintenance works gets reduced.This necessitates the development of a system that helps us in detecting the
unusual current consumption so that all the undesirable anomalies can be avoided. Presently there are no such
systems that help us in detecting this problem. This paper aims in developing such a system using a
microcontroller that digitally notifies the loco pilot for any unusual current consumption so that if such a
situation should arise the specific faulty motor can be isolated before it gets damaged.
KEY WORDS:Current detection, Locomotive, Microcontroller, Traction motor, Wheel slip

I. INTRODUCTION
The electric Locomotives (WAP4 &
WAG7) used by the Indian Railways employs 6 DC
series motors. The improvement of adhesion
characteristics is important in electric commuter
train. Wheel slip is a major problem arising in this.
The anti-slip/skid re-adhesion control system based
on disturbance observer and sensor-less vector
control
is
already
been
proposed[1].AntislipReadhesion Control Based on
Speed-Sensorless Vector Control was done earlier in
Japanese railways[2].But this will not suit our
railway system.

II. OPERATION OF A LOCOMOTIVE
The electric locomotive basically works at
25 KV, 50Hz supply. The 25KV AC supply is drawn
from overhead equipment[3]. The supply of
electricity is through an overhead system of
suspended cables known as the catenary. A contact
wire or contact cable actually carries the electricity.
The locomotive is equipped with two pneumatically
controlled pantographs. The supply from overhead
wires is drawn through these pantographs inside to
the loco. The pantographs transfer the power to
transformer after passing through the normally closed
vacuum circuit breaker. Output voltage of the tap
changer is fed to the primary of the main transformer.
The main transformer steps down the voltage to a
lower level. The voltage from the secondary of main
transformer is fed to bridge rectifier and then fed to
traction motor through the motor contactors and
reversors. There are 6 traction motors which works
parallel to provide the tractive effort for hauling the
train.
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III. POWER CIRCUIT OF THE
LOCOMOTIVE
The electrical power circuit of the loco
consists of the following main parts:[4]

IV. TRACTION MOTOR
These are DC series motor which produce
maximum torque while starting and suitable for quick
acceleration. The speed can be easily varied by
varying the input voltage. They are able to move very
large shaft loads when it is first energized. The
amount of current that passes through the winding
determines the amount of torque the motor shaft can
produce. Since the series field can carry large
amounts of current it produces large torque.

of problem usually involves the motor overheating or
not being able to pull its rated load. This type of
problem is different from an open circuit because the
motor is drawing current and trying to run. Since the
motor is drawing current, you must assume that there
is no open circuit. It is still possible to have brush
problems that would require the brushes to be reseated or replaced. Other conditions that will cause
the motor to overheat include loose or damaged field
and armature coils. The motor will also overheat if
the armature shaft bearing is in need of lubrication or
is damaged. The bearing will seize on the shaft and
cause the motor to build up friction and overheat. If
either of these conditions occurs, the motor should be
fixed for extensive repairs. When the motor is
restarted after repairs have been made, it is important
to monitor the current usage and heat buildup.

V. WHEEL SLIP

All traction motors are connected in parallel.
For electric braking, motors are disconnected from
silicon rectifier and the armatures are connected to
the braking resistances. The motor enters generating
action thus reducing the kinetic energy. The final
braking effort is by brake shoes. This type of braking
is called dynamic braking. This reduces the braking
effort and increases the efficiency of braking thereby
reduces the wear and tear of the brake shoes.
4.1 TRACTION MOTOR CURRENTS
The current flowing through the traction
motor throughout the course ofits use is not constant.
It can vary from time to time. The motor has the
tendency to consume current that is above the
maximum or below the minimum rating. If it
consume say an increase in 10% of normal current
continuously it is enough to cause flashover or
burnouts. The most likely problem that will occur
with the series motor is that it will develop an open in
one of its windings or between the brushes and the
commutator. Since the coils in a series motor are
connected in series, each coil must be functioning
properly or the motor will not draw any current.
When this occurs, the motor cannot build a magnetic
field and the armature will not turn. Another problem
that is likely to occur with the motor circuit is that
circuit voltage will be lost due to a blown fuse or
circuit breaker [5]. The motor will respond similarly
in both of these conditions. It is possible that the
motor will develop a problem but still run. This type
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When the train is in an uphill or downhill
motion there is tendency for the wheels to slip with
respect to the track. The speed of the motor increases
and the motor consumes abnormal power without
doing any work. Although the effect is undesirable it
is a perfectly natural phenomenon that cannot be
avoided. The wheel slip depends on the geographical
terrain, the alignment of wheel with track, the
climatic conditions and various others. Many
effective measures have been employed presently to
avoid this effect [6].
Wheel slip on locos such as the WAP4/WAG-7, is detected by a relay designated 'QD'
which is a current differential relay. It detects the
difference in the current flow between two traction
motors. If all the traction motors are running at
uniform and equal speeds, the armature of the relay
remains balanced. However, if any of the axles are
slipping, the current to this motor is slightly reduced
producing a current imbalance in relay QD which is
then triggered. QD gives a repeat to a relay 'Q48'
which in turn may activate some automatic wheelslip reduction procedures. Operation of relay Q48
also lights the LSP (Signal lamp to indicate WheelSlip) on the driver's desk.WAG-7 and WAP- 4 have
been provided with mainly three methods to
minimise wheel slip:
5.1 Sanders to improve adhesion: Sander contains
sand that gets sprayed in between the wheel and track
in case of wheel slip to increase adhesion. Hence the
friction increases and the slipping reduces. Sanders
can be operated automatically by relay Q48 or
manually.
5.2 Auto-Regression of the Tap-Changer to reduce
tractive effort: Q-48 also gives an impulse to relay Q51 (Relay for Auto-Regression of Tap-Changer) to
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SmrithiRadhakrishnan et al Int. Journal of Engineering Research and Applications www.ijera.com
ISSN : 2248-9622, Vol. 4, Issue 3( Version 4), March 2014, pp.20-25
reduce the notches which in turn lowers the voltage
to the traction motors thereby reducing the tractive
effort.
5.3 Field Weakening (Weak Field Operation): The
DC series motors have their fields wound in series
with the armature winding. Normally, the current
through the field and the armature is equal but if the
current through the field is partially bypassed, the
torque of the motor is reduced. Hence, by shunting
the field, the tractive effort of the motor is reduced.
During wheel slipping, weak field is usually
introduced on the leading axles of both the bogies
because these are usually the ones to slip first due to
dynamic weight transfer which tend to reduce the
weight on the leading axles and proportionately
increases weight on the trailing axles.

VI. PROBLEMS OF THE PRESENT
SYSTEM
The traction motors consumes a reasonable
amount of the total cost that is used to build up a
locomotive hence its frequent failures and
maintenance is not really appreciated. The lesser the
failure the more efficient it is and the lesser the
maintenance required. Probability for a faulty traction
motor in the locos received for maintenance in the
loco shed is comparatively high. The problem is that
currently there are no such systems that can prevent a
motor from behaving abnormally. Continuous
consumption of a small increase in current is enough
to overheat and cause failure of the motor.
Presently there is no reasonable ways for the
loco pilot to understand the current consumption
behavior of a motor and avoid the flashing and other
problems related to these motors.
QD used to detect wheel slip is efficient
method for avoiding it but in a bogie QD is present
only for 1 set of motor the third remains free similar
is the case of other bogie. In total the QD is present
only for 4 out of 6 motors[7]. The slipping in other
two motors cannot be understood by the loco pilot. If
at all continuous slipping is reported even after
primary protection schemes it is avoided by reducing
the current to a whole bogie that is 3 motors hence
overall speed reduces and affects the efficiency of the
engine.
What we need is a system for the loco pilot
to actually isolate the motor that is carrying unusual
currents and protect the traction motor before the
event of its failures or faults like flashover, pitting,
contactor burning etc. The present isolation scheme is
based on the assumptions made by the loco pilot.

VII. PROBLEM SOLUTION
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The main objective of any shed would be to
make the machine as long lasting as possible with
minimum amount of maintenance and good
efficiency. The solution to this problem would be the
development of a system that would help the loco
pilot to find out which motor is actually consuming
the unusual current and isolate it so that the other
motors work and produce the necessary effort to pull
the freight. This would help a lot to increase the
efficiency of the engine.The present system is an
electromechanical system. A digital system can do all
the above functions.

VIII. BLOCK DIAGRAM
110-5v

6T
M
i/p

I v

LED

ATMega
16

(150A60mV)

The 6 traction motor inputs are fed to a
microcontroller. The TM currents have a max limit of
1500A and it needs to be converted. Suitable
converters are used to convert the current to
microvolt level like Hall Effect converter or transimpedance converter.
The control voltage 110v from the desk is
stepped down using a SMPS circuit to 5v and fed to
the microcontroller for its working. The output is
displayed by a series of LEDâ&#x20AC;&#x2122;s. There are 12 LEDâ&#x20AC;&#x2122;s
in total 6 indicating high current consumption and the
other 6 indicting low current consumption. The high
or low parameter is set on the basis of the difference
current in the QD. That is the maximum limit is 200A
in the difference relay. The current difference should
not be below or above 200A.

IX. TECHNOLOGICAL
BACKGROUNDS
The design and construction of the current
detection system has several features that requires
specifications for each subsystem. By breaking the
design into subsystems a better understanding of the
requirements needed to fulfill the objectives is
gained.

X. MICROCONTROLLER
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SmrithiRadhakrishnan et al Int. Journal of Engineering Research and Applications www.ijera.com
ISSN : 2248-9622, Vol. 4, Issue 3( Version 4), March 2014, pp.20-25
The use of the Microcontroller reduces the
complexity of the circuitry and controls all the
functions needed for the system. Hence a
microcontroller that exhibits small size, cheap,
external interrupts, UART, small flash memory,
processing
speed
is
needed.
ATMega16
microcontroller is selected that meets all the required
needs for the system. The flash memory is to store
the log data through the run time. The AVR i-Board
designed is perfect for the system. The features
included in i-Board are:
 ATMEL AT-Mega 16 with16kb flash
memory
 In system programmable
 On board programmer
 On board regulated power supply
 Power indicator LED
 3 ON/OFF switch for external interrupts
 On board LCD connector

XI. HALL EFFECT TRANSDUCER
A Hall Effect sensor is a transducer that
varies its output voltage in response to a magnetic
field. In its simplest form, the sensor operates as an
analogue transducer, directly returning a voltage.
Electricity carried through a conductor will produce a
magnetic field that varies with current, and a Hall
sensor can be used to measure the current without
interrupting the circuit. Typically, the sensor is
integrated with a wound core or permanent magnet
that surrounds the conductor to be measured.
The present system employs current shunt
resistors to convert the high traction motor output
current to measurable values. The main advantage of
hall sensors compared to these are that unlike the
current shunt sense resistor which can have thermal
and temperature heat dissipation issues, it does not
become hot.An example connection of a hall sensor
is shown below. The diagram shows a 12 Volt DC
wall adapter supplying voltage to a 8 Volt
regulator. The 7808 Volt regulator puts out a very
stable DC voltage.

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This is very important because the sensor
output is only ~0.032 Volts per Amp that it measures,
so if the voltage you are supplying the sensor is
noisy, your data will get lost in the noise. The
ground is shared throughout the circuit. The sensor
used for our system is closed loop precise hall current
sensor CYHCS-SH.
The main features are
 Linear output
 AC or DC current sensing
 Fast response time
 Output voltage isolation from input
 Minimum energy dissipation
 Maximum current limited only by conductor
size
 Adjustable performance and built-in
temperature compensation assures reliable
operation
 Accurate, low cost sensing
 Operating temperature range -25 °C to 85 °C
The cost of a Hall Effect sensor is around
Rs: 1550. The datasheets is as follows:

XII. SMPS (110V TO 12V)
A 80 W Single O/P DC-DC converter
110VDC I/P manufactured by the STARVOX
Electronics Limited can be used for conversion of the
110V control voltage available at the drivers panel to
12v DC. This 12v is stepped down to 5v using a 7805
IC. This 5v DC is given as the VCC to the AT-Mega
Microcontroller.

XIII. PERFORMANCE EVALUATION
The above described system can pose the
solution for the whole problems described above. We
have already seen the subsection earlier the traction
motor currents reach the microcontroller where the
intelligent computations are done. An iterative
continuous process is carried out by the
microcontroller. Firstly the mean of whole input
currents are found out. This value is stored in the
temporary register and then the currents are
averagedseparately. These separate mean currents are
compared to that of the total mean calculated first. If
the difference exceeds a tolerance level of 200A the
corresponding LED output glows (high or low). After
that the current responsible for glowing the LED is
omitted and rest of the currents are compared. The
comparison is made for both high and low conditions
that are high current consumption and low current
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consumption. This finishes one cycle after this these
conditions are repeated. Sometimes due to transient
fault the current may rise but it reduces to normal
level. So it should be checked and only if the
condition is persisting after repeated cycles then the
motor needs to be isolated. Once isolated the loco
pilot cannot reinstall it until it is checked thoroughly
by the shed technicians. The technicians can get a
complete log of the run time problems through the
serial communication port (RS232) in the i-Board of
the microcontroller. Hence in this way the motor
carrying abnormal current is notified to the loco pilot
in a simple manner and he can protect it before it gets
flashed or burned. The system described above can
be easily manufactured and installed but the
governing factor is the cost. The system costs a
reasonable amount but less compared to the amount
that it is saving by protecting the traction motors.
Hence in every manner we can say that it is an
excellent system that needs to be installed into the
locos.
The main advantages of the system are:
 Compact
 Since microcontroller used it is flexible. It
can be modified based on requirements
 Since the Hall Effect sensors are used to
measure the high currents, there is no actual
contact to these high currents hence proper
isolation can be achieved.
 The hall-effect sensor does not get heated up
as the current shunt resistor employed now.
 The microcontroller is cheap and has flash
memory that helps in data logging.
 The whole system has a comparatively good
efficiency and performance
The main disadvantages are:
 The cost of hall effect sensor and the SMPS
is comparatively high
 A small deviation in the output of the SMPS
makes the controller inactive
 Troubleshooting the controller is a
troublesome process.

XIV. FUTURE POSSIBILITIES






The RS-232 communication port of ATMega Microcontroller can be used for
further communication purposes. It can be
modified to transmit the run time details as
such to nearest stations.
Feedback circuits can be incorporated to
make
the
circuit
automatic.
As
microcontrollers are used it can carry out
multiple tasks at the same time. Hence many
automatic feedback circuits can be installed.
Many
automatic
correction
circuits
employed are electromagnetic relays it can
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be replaced using this microcontroller thus
reducing the size and improve efficiency as
the system becomes intelligent.
The whole loco operation can be controlled
using advanced microcontrollers i.e.
automatic pilot systems can be installed in
the locos also.
The MEMU systems used now can be
further simplified and the system becomes
more rugged.
Every systems, not only the current system
discussed in the project can be monitored
and the efficiency of the operation of
locomotive increases at an alarming rate.

Development of a new traction control
method to suppress wheel-slip of electric
locomotives, by Yamshita.M, Soeda,T,
publication year:2012

[7]

Distribution of traction return current in AC
and DC electric railway systems by
Mariscotti.A, Power delivery, IEEE
transactions
on
volume:18,
Issue:4,
publication year:2003,pages:1422-1432

XV. CONCLUSION
This digitalized current detection scheme is
a very helpful system both from the point of view of
the Loco pilot and the technicians at the maintenance
shed. With the installation of such a device into the
locomotives the chances of errors can be reduced by
a great percentage. The main objective of any shed
would be to make the machine as long lasting as
possible with minimum amount of maintenance and
this can be achieved if suitable systems are present in
the locomotive that overcomes any change from the
normal behavior.
This system would help in long lasting of
the traction motors used and helps in increasing the
efficiency of the locomotive. This current detection
scheme helps the loco pilot to isolate the faulty ones
and proceed with maximum efficiency with rest of
the traction motors.

SmrithiRadhakrishnan
has
obtained her BTech degree with
Honoursin
Electrical
and
Electronics Engineering from
Calicut University Institute of
Engineering
and
Technology,Kerala in 2012.
Currently she is doing her ME in
Power Systems Engineering at Sri Ramakrishna
Institute of Technology, Tamilnadu.She has
published one research paper in a national
conference. Her special areas of interest are power
system protection, machine design and micro grid.

S.Sangeetha has obtained her
BE degree in Electrical and
Electronics Engineering from
Bharath Institute of Science
and Technology, Tamilnadu in
2001. She received her ME in
Power Systems Engineering
from
Sona
College
of
Technology, Tamilnadu in
2006. At present she is working as Assistant
Professor in EEE Department at Sri Ramakrishna
Institute of Technology and persuing PhD in the field
of renewable energy. She published two research
papers in national conferences.Her areas of interest
are power system and renewable energy.